Journal
CELL CYCLE
Volume 20, Issue 22, Pages 2337-2347Publisher
TAYLOR & FRANCIS INC
DOI: 10.1080/15384101.2021.1986317
Keywords
Aging; reactive oxygen species; redox; longevity; epigenetics; h3k4me3; hormesis
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Funding
- Breakthrough in Gerontology award from the American Federation of Aging Research
- NIH [GM122506]
- BrightFocus ADR Fellowship [A2019250F]
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Studies have shown that genetically identical animals in the same environment can have variability in lifespan, with stochastic factors playing a role. Recent research suggests that variations in reactive oxygen species levels early in life can contribute to lifespan variability and act as stochastic factors in aging. Developmental events can positively influence lifespan and stress responses through a redox-sensitive epigenetic regulator.
Studies in Caenorhabditis elegans have revealed that even a genetically identical population of animals exposed to the same environment displays a remarkable level of variability in individual lifespan. Stochasticity factors, occurring seemingly by chance or at random, are thought to account for a large part of this variability. Recent studies in our lab using C. elegans now revealed that naturally occurring variations in the levels of reactive oxygen species experienced early in life contribute to the observed lifespan variability, and likely serve as stochasticity factors in aging. Here, we will highlight how developmental events can positively shape lifespan and stress responses via a redox-sensitive epigenetic regulator, and discuss the outstanding questions and future directions on the complex relationship between reactive oxygen species and aging.
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